Revolutionary images of the birth of crystals
Crystallization is a chemical and physical process used in many fields, from the pharmaceutical industry to food processing. It is used to isolate a gaseous or liquid substance in the form of crystals. However, this phenomenon is not unique to industry; it is ubiquitous in nature and can be seen, for example, in snowflakes, coral or kidney stones.
For crystals to form from substances, they must first go through a crucial stage called nucleation. It is during this first phase that the molecules begin to arrange themselves to form ‘nucleus’, stable clusters of molecules, which leads to the development and growth of crystal. This process occurs stochastically, meaning it is not predictable when and where a nucleus form. “Until now, scientists have been struggling to visualize this first stage at the molecular level. The microscopic picture of crystal nucleation has been under intense debate. Recent studies suggest that molecules seem to form some disordered organization before the formation of ‘nuclei’. Then how does the crystalline order emerge from them? That is a big question!,” explains Takuji Adachi, assistant professor in the Department of Physical Chemistry at the UNIGE Faculty of Science.
Capturing one crystal nucleation event at a time
Takuji Adachi’s team, supported by two researchers from the Department of Chemistry at McGill University (Nathalie LeMessurier and Lena Simine), has taken a decisive step by succeeding in observing the nucleation process of an individual crystal at the micrometric scale by optical spectroscopy. “We have succeeded in demonstrating and visualizing the organization and formation of molecular aggregates that precede crystallization,” explains Johanna Brazard, a researcher in the Department of Physical Chemistry and co-first author of the research.
To observe this phenomenon, the scientists combined Raman microspectroscopy — a technique based on the interaction of light with matter to obtain information on its composition — and optical trapping. “We used lasers to highlight the molecular structure during the nucleation but also to induce the nucleation phenomenon and thus be able to observe it and record its spectral imprint,” explains Oscar Urquidi, a doctoral student in the Department of Physical Chemistry and co-first author of this research. The model substance chosen to conduct these experiments was glycine, an amino acid that is an essential building block of life, dissolved in water.
“Our work has revealed a stage of crystallization that was previously invisible, says Takuji Adachi. Visualizing more precisely and better understanding what is happening at the molecular level is very useful for directing certain manipulations more effectively.” In particular, this discovery could make it easier to obtain purer and more stable crystal structures for certain substances used in the design of many drugs or materials.